How does HFOV work? John F Mills MBBS, FRACP, M Med Sc, PhD Neonatologist Royal Children s Hospital. Synopsis

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1 How does HFOV work? John F Mills MBBS, FRACP, M Med Sc, PhD Neonatologist Royal Children s Hospital Synopsis Definition of an oscillator Historical perspective Differences between HFOV and CMV Determinants of gas exchange Oxygenation CO 2 removal 1

2 Definitions High frequency oscillatory ventilation A type of artificial ventilation in which an oscillatory flow with clearly defined inspiratory and expiratory phases is generated in the lung at a frequency greater than 2 Hz & Chang 1984 Definitions High frequency oscillatory ventilation A type of artificial ventilation in which an oscillatory flow with clearly defined inspiratory and expiratory phases is generated in the lung at a frequency greater than 2 Hz & Chang

3 Definitions High frequency oscillator A machine which generates an oscillatory waveform at the airway opening, with the following characteristics: Frequency above 2 Hz (usually 5-15 Hz) Active inspiration and expiration Tidal volumes less than anatomic dead-space Frequently characterised by the method of exhalation Historical perspective Scotter et al (1967): diffusion of oxygen through a cylinder augmented by application of an oscillatory waveform to one end Lunkenheimer et al (1972): CO 2 transport in apnoeic dogs improved if lung exposed to an oscillatory waveform Bohn et al (1980): prolonged normocarbia in five beagles using a rudimentary oscillator (possible despite tidal volume 40% of anatomic dead-space Butler et al (1980): first report in humans. Four healthy volunteers, and subsequently 12 patients (three days to 74 years) oscillated for one hour. CO 2 clearance easily achieved, oxygenation stable and pulmonary shunt decreased 3

HFOV vs IPPV Fundamental differences IPPV HFOV Rate 0-150 180-900 Tidal volume 4-20 ml/kg 0.

4 HFOV vs IPPV Fundamental differences IPPV HFOV Rate Tidal volume 4-20 ml/kg ml/kg Alveolar pressure 0->50 cm H 2 O cm H 2 O EELV Low Normal Gas flow Low High HFOV vs IPPV Differences in ventilator waveforms & Gerstman et al 4

5 Determinants of gas exchange during HFOV Oxygenation Determinants of gas exchange CMV vs HFOV CMV Rate/Frequency Tidal Volume/PIP PEEP I-Time FIO 2 Ventilation Oxygenation HFOV Frequency Amplitude I-Time % Mean Airway Pressure FIO 2 5

Determinants of oxygenation Mean airway pressure

lung units and optimising the alveolar surface area

6 Determinants of oxygenation Mean airway pressure Oxygenation is determined by lung volume The mean airway pressure (P aw ) setting is used to determine lung volume by recruiting atelectatic lung units and optimising the alveolar surface area for gas exchange V P Determinants of oxygenation Volume history 6

7 Determinants of oxygenation Volume history PaO 2 (mm Hg) P AW (cm H 2 O) & Mills JF PhD Thesis Determinants of oxygenation Volume history V Successful application of HFOV is dependent upon ventilation with the lung recruited (open lung strategy, high lung volume strategy) Alveolar recruitment manoeuvres are required on initiation of HFOV, and after disconnection/suction Regular re-assessment of P aw to ensure continuous ventilation at optimum lung volume P 7

8 Determinants of oxygenation Impact of P aw on PVR PVR is increased with: Atelectasis - loss of support for extra-alveolar vessels Overdistension - compression of alveolar capillary bed Determinants of gas exchange during HFOV Carbon dioxide removal 8

9 CMV vs HFOV Alveolar ventilation during CMV is defined as: f x V T Alveolar ventilation during HFOV is defined as: f x V T 2 During HFOV, V T is determined by stroke volume of the ventilator Stroke volume The stroke volume will increase if The amplitude increases The frequency decreases (longer cycle time) Stroke volume 9

Amplitude The amplitude is created by the distance that the piston/ diaphragm moves. This movement results in a gas volume displacement and a visual chest wiggle.

10 Amplitude The amplitude is created by the distance that the piston/ diaphragm moves. This movement results in a gas volume displacement and a visual chest wiggle. It may also be described as the peak-to-trough swing around the P aw Frequency Secondary control of CO 2 is provided by the frequency If the amplitude controls the force with which the piston moves, the frequency controls the time allowed for the piston to move The lower the frequency setting, the greater the volume displacement The higher the frequency setting, the smaller the volume displacement 10

11 Frequency The frequency is generally set according to the size of the patient, and the type of lung disease Frequency may need to be adjusted from the initial setting Frequency is not weaned in the same way as it is during CMV decreasing frequency with HFOV actually increases ventilatory support Effect of resonant frequency Inspiratory time Allows more time for piston travel resulting in larger tidal volume More pronounced at lower frequencies 11

12 Bias flow The ventilator bias flow produces the P aw of the system, and also helps to flush the CO2 that accumulates in the circuit during the expiratory phase If ventilation is problematic, increasing or decreasing flow may be helpful Questions 12

3100A Competency Exam

NAME DATE (Circle the appropriate answer) 3100A Competency Exam 1. Of the following, which best describes the mechanics of ventilation used by the 3100A? a. Active inspiration with passive exhalation b.